Related papers: Statistical Inference for Online Algorithms

Statistical Inference for Online Algorithms

URL: http://arxiv.org/abs/2505.17300v1
Date: Thu, 22 May 2025 21:31:49 GMT
Title: Statistical Inference for Online Algorithms
Authors: Selina Carter, Arun K Kuchibhotla,
Abstract summary: We propose a new type of inference based on the output of online algorithms em without estimating the variance.<n>We focus on gradient descent with Polyak averaging to understand the practical performance of the proposed method.
Score: 2.7624021966289605
License: http://creativecommons.org/licenses/by-nc-nd/4.0/
Abstract: Construction of confidence intervals and hypothesis tests for functionals based on asymptotically normal estimators is a classical topic in statistical inference. The simplest and in many cases optimal inference procedure is the Wald interval or the likelihood ratio test, both of which require an estimator and an estimate of the asymptotic variance of the estimator. Estimators obtained from online/sequential algorithms forces one to consider the computational aspects of the inference problem, i.e., one cannot access all of the data as many times as needed. Several works on this topic explored the online estimation of asymptotic variance. In this article, we propose computationally efficient, rate-optimal, and asymptotically valid confidence regions based on the output of online algorithms {\em without} estimating the asymptotic variance. As a special case, this implies inference from any algorithm that yields an asymptotically normal estimator. We focus our efforts on stochastic gradient descent with Polyak averaging to understand the practical performance of the proposed method.

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